Pseudogene

About: Pseudogene is a research topic. Over the lifetime, 5528 publications have been published within this topic receiving 336634 citations. The topic is also known as: Ψ & pseudogenes.

Mutations in SBDS are associated with Shwachman–Diamond syndrome

Abstract: Shwachman-Diamond syndrome (SDS; OMIM 260400) is an autosomal recessive disorder with clinical features that include pancreatic exocrine insufficiency, hematological dysfunction and skeletal abnormalities. Here, we report identification of disease-associated mutations in an uncharacterized gene, SBDS, in the interval of 1.9 cM at 7q11 previously shown to be associated with the disease. We report that SBDS has a 1.6-kb transcript and encodes a predicted protein of 250 amino acids. A pseudogene copy (SBDSP) with 97% nucleotide sequence identity resides in a locally duplicated genomic segment of 305 kb. We found recurring mutations resulting from gene conversion in 89% of unrelated individuals with SDS (141 of 158), with 60% (95 of 158) carrying two converted alleles. Converted segments consistently included at least one of two pseudogene-like sequence changes that result in protein truncation. SDBS is a member of a highly conserved protein family of unknown function with putative orthologs in diverse species including archaea and eukaryotes. Archaeal orthologs are located within highly conserved operons that include homologs of RNA-processing genes, suggesting that SDS may be caused by a deficiency in an aspect of RNA metabolism that is essential for development of the exocrine pancreas, hematopoiesis and chrondrogenesis.

ceRNA Cross-Talk in Cancer: When ce-bling Rivalries Go Awry

Abstract: The cancer transcriptome is characterized by aberrant expression of both protein-coding and noncoding transcripts. Similar to mRNAs, a significant portion of the noncoding transcriptome, including long noncoding RNAs and pseudogenes, harbors microRNA (miRNA)-response elements (MRE). The recent discovery of competitive endogenous RNAs (ceRNA), natural decoys that compete for a common pool of miRNAs, provides a framework to systematically functionalize MRE-harboring noncoding RNAs and integrate them with the protein-coding RNA dimension in complex ceRNA networks. Functional interactions in ceRNA networks aid in coordinating a number of biologic processes and, when perturbed, contribute to disease pathogenesis. In this review, we discuss recent discoveries that implicate natural miRNA decoys in the development of cancer. Significance: Cross-talk between ceRNAs through shared miRNAs represents a novel layer of gene regulation that plays important roles in the physiology and development of diseases such as cancer. As cross-talk can be predicted on the basis of the overlap of miRNA-binding sites, we are now one step closer to a complete functionalization of the human transcriptome, especially the noncoding space. Cancer Discov; 3(10); 1113–21. ©2013 AACR .

The Complete Human Olfactory Subgenome

Abstract: Olfactory receptors likely constitute the largest gene superfamily in the vertebrate genome. Here we present the nearly complete human olfactory subgenome elucidated by mining the genome draft with gene discovery algorithms. Over 900 olfactory receptor genes and pseudogenes (ORs) were identified, two-thirds of which were not annotated previously. The number of extrapolated ORs is in good agreement with previous theoretical predictions. The sequence of at least 63% of the ORs is disrupted by what appears to be a random process of pseudogene formation. ORs constitute 17 gene families, 4 of which contain more than 100 members each. "Fish-like" Class I ORs, previously considered a relic in higher tetrapods, constitute as much as 10% of the human repertoire, all in one large cluster on chromosome 11. Their lower pseudogene fraction suggests a functional significance. ORs are disposed on all human chromosomes except 20 and Y, and nearly 80% are found in clusters of 6-138 genes. A novel comparative cluster analysis was used to trace the evolutionary path that may have led to OR proliferation and diversification throughout the genome. The results of this analysis suggest the following genome expansion history: first, the generation of a "tetrapod-specific" Class II OR cluster on chromosome 11 by local duplication, then a single-step duplication of this cluster to chromosome 1, and finally an avalanche of duplication events out of chromosome 1 to most other chromosomes. The results of the data mining and characterization of ORs can be accessed at the Human Olfactory Receptor Data Exploratorium Web site (http://bioinfo.weizmann.ac.il/HORDE).

Processed Pseudogenes: Characteristics and Evolution

Abstract: The processed pseudogenes reported to date fall into three categories: those that are a complete copy of the mRNA transcribed from the functional gene, those that are only a partial copy of the corresponding mRNA, and those that contain sequences in addition to those expected to be present in the mRNA. The general structural characteristics of these processed pseudogenes include the complete lack of intervening sequences found in the functional counterparts, a poly A tract at the 3' end, and direct repeats flanking the pseudogene sequence. In all the cases studied, these pseudogenes have been found to be on a different chromosome from their functional counterpart. These characteristics have led investigators to suggest that an RNA intermediate, in many cases the mRNA of the functional gene, is involved in the production of these pseudogenes. The mechanism by which processed pseudogenes arose involves the integration of the mRNA, or its cDNA copy, into a staggered chromosome break, followed by DNA synthesis and repair. I suggest that all the transcripts that gave rise to these pseudogenes were actually produced in the germ line cell. The transcripts that gave rise to the processed pseudogenes that are direct copies of the corresponding mRNA resulted from RNA polymerase II transcription of the functional counterpart. Pseudogenes that are not a direct copy of the corresponding mRNA may have resulted from RNA polymerase III transcription. If this is indeed the case, one need not postulate the involvement of retroviruses to explain the presence of processed pseudogenes corresponding to genes that are not expressed in the germ line. Following the integration event, processed pseudogenes can no longer be transcribed to produce the functional mRNA from which they arose. This inability to be transcribed by RNA polymerase II is not surprising considering that processed pseudogenes seem to be randomly integrated into the genome. Therefore, integration of a processed pseudogene such that RNA polymerase II transcriptional promoters are correctly positioned 5' to the resultant pseudogene is an unlikely event. The presence of processed pseudogenes seems peculiar to mammals. In fact, evolutionary studies indicate that processed pseudogenes are of relatively recent origin. In fact, at least one processed pseudogene, the human DHFR psi 1, has been formed so recently that it is polymorphic.